DE973132C - Voltage comparison indicator tubes - Google Patents

Description

(WiGBl. P. 175)

ISSUED DECEMBER 10, 1959

L 857p FIIIc / 21g

Addition to patent 950

The main patent 950946 deals with a voltage comparison indicator tube with two with the to compare voltages connected electrodes, which are crossed in such a way that in opposite directions Light pattern parts immigrating into the symmetrical position, equal voltage and immigrating in opposite directions Light pattern parts show voltage difference.

In the case of a voltage comparison indicator tube with two voltages connected to the voltages to be compared Electrodes in which, according to main patent 950946, these electrodes are crossed in such a way that oppositely immigrating luminous pattern parts in the symmetrical position voltage equality and Illuminating pattern parts migrating in opposite directions indicate a voltage difference, according to the invention the separation point between the deflection electrodes of the individual display systems a shielding electrode covered, so that the annoying intersections of the luminous sector edges are avoided. The arrangements according to the invention reduce the image-disrupting effect the separation point canceled. It is also achieved that with a suitable design and arrangement the separating electrode, the individual luminous images for touching or covering can be brought. A precise reading is also obtained when comparing the voltage.

As an electron source for the individual, created by the parts of the crossed struts Generator systems can use separate cathodes. A simpler system structure becomes

909 665/26

but achieved in that the individual systems Λ-οη a common cathode, which - if necessary - Is preferably surrounded by a common display grid, are fed. If Each deflection system is surrounded by a display grid, the deflection systems can be passed through affect the display grid separately. For example, the luminous image of a system can be passed through A voltage that is negative in relation to the cathode ίο can be extinguished. This can be done for AM / FM combo Display tubes be of importance, as the multiple luminous images during AM reception by the Suppression of one or more luminous images become clearer.

The subdivision of the individual deflection systems can take place along the length of the cathode groove. One A more expedient arrangement is achieved when the division is along the axial cathode he follows. A desired overlap of the individual luminous patterns can be achieved through the application electron-optical systems, which have a distracting effect, preferably in planes which go through the cathode axis, to the electrons passing from the cathode to the light anode exercise. This deflection is expediently carried out in such a way that the sharply imaging property of the individual systems is retained or is still being improved. This electron optical The system is generally designed in such a way that it can simultaneously display the disturbing separation point of the individual deflection systems arranged along the axial cathode Makes the screen ineffective. The invention also provides the degree of overlap of the To change the luminous images of the individual systems on the luminescent screen through external tension and to use this effect for additional display purposes. For example, this can be if the tuning indicator tube used to tune receivers for frequency-modulated carriers will use to display the carrier. If a display tube is used for a combination display for FM and AM display, so can the luminous image of a deflection system with AM reception thus removed from the luminescent screen or moved on the screen.

As a deflection element in the individual control systems, the deflecting ones can be used in a known manner Properties of one or more control elements installed parallel to the cathode, for example of grids or of annular metal sheets, which are arranged perpendicular to the axial cathode are, or of struts or of a sheet metal, the generatrix which is parallel to Cathode run, be applied. However, particularly advantageous embodiments result then, if of the imaging property of two relatively closely adjacent electrodes, for example in the form of round or profiled struts or sheets, use is made. In general the deflection struts in the individual systems have the same distance. For special cases it can be advantageous to make the spacing of the deflection struts unequal in the individual systems do. This measure can particularly prevent the effects of assembly tolerances, because the required overlap of the luminous images is still guaranteed when the voltages are equal is. As is known, the electrodes arranged in this way produce a luminous image when the voltage is equal, depending on the tension level of the webs by a more or less narrow luminous line with ' two adjacent shadow sectors is characterized. If there is a difference in voltage, it wanders middle luminous line according to the size and the sign of the voltage difference from a Middle position, similar to the pointer of a measuring instrument. The size of the illuminated pictures, in the present case The width of the luminous bar and the size of the shadow sectors depend on the trap Height of the selected voltage level of the two control electrodes. This luminous effect can be Exploit them appropriately. For example, it can be used when the display tube for displaying the tuning status is applied by FM receivers to use for carrier display. It must by special circuit arrangement or by a special amplifier system the voltage level of the two electrodes by a carrier-dependent Control voltage can be changed.

It is expedient to provide for the connection of the direct voltage in the individual deflection systems to be arranged alternately, which is particularly advantageous when a voltage difference occurs Illuminated image shifts running in opposite directions result.

The embodiments given below represent only exemplary embodiments. They are with regard to the tuning accuracy and the good and unambiguous recognizability of the luminous image is considered to be particularly advantageous. A Embodiment of the invention is shown in Fig. Ι in the side view, in Fig. 2 in plan and in

Fig. 3 shown in front view.

The axial cathode 1 is supported by a display grid 2, which is preferably at cathode potential, of two round struts 3, 4, to which the equivalent voltage is applied, of one opposite the Cathode at positive potential elec- "" trode5, which are held by the supports 8 and 9 and which are preferably indicated in FIGS Has the shape of a curved piece of sheet metal, and surrounded by the luminescent screen 7. In these exemplary embodiments as well as in the "5 in the following, only part of the circumference of the cathode is used for the lighting system. the The invention provides the specified system arrangement along the circumference several times to attach or to use the unused cathode part for other discharges. For example an amplifier system can be arranged on the unused circumference of the axial cathode. This amplifier system can also be used in the known manner for amplification or control of the the voltage on the display electrodes

be used. The top of the system is closed off by the opaque one on one opposite the Cover cap located at positive potential 6. In general, this cover cap connected to the fluorescent screen potential. This cap can with a suitable design with a or several recesses. Another suitable cap can also be used in place of the cap Use an electrode that may be connected to the ίο cap. In this case, this represents Arrangement represents a system for generating a non-position-changeable luminous image. By suitable Design, the most varied of luminous images can be generated, z. B. a line or point or several lines or rows of points, similar to a scale or the like. As particularly advantageous becomes a wedge-shaped formation of the recess and thus a wedge-shaped luminous image design viewed. Due to the position of the changeable luminous image or images that are in the present. Let the case be understood as the pointer of a measuring instrument, of the other deflection system or systems to the fixed luminous images, which in the present case are used as a scale of a measuring instrument can be understood, the voltage magnitude or voltage difference is shown. The luminance of the individual luminous images can be controlled by suitable arrangements, z. B. in a known manner through the display grid. This allows the luminous image of individual systems be wiped out. This procedure becomes particularly important when taking a measurement with a different luminous scale is desired.

By between the sheet metal ring 5 and the upper edge of the cap 6 or the lower The electrical field that forms on the edge of the fluorescent screen can affect the mutual position of the illuminated images can be changed on the fluorescent screen. According to the present invention, this change of position takes place in such a way that that the display values are not changed. By influencing these electric fields is it is possible to arrange the individual luminous images generated on the luminescent screen next to one another or to cause them to overlap. At the same time, they carry through their special field-shaping properties Effect to an increase in the distraction sensitivity of the distraction organs. The electrodes 3, 4 are crossed roughly in the middle of the height of the screen. However, you can also do this in the individual Systems arranged individually and inside or outside the tubular flask crosswise or in be connected in another way. The resulting fluorescent screen pattern when operating the Tube is in Fig. 4 for the state of voltage equality, in Figs. 5 and 6 for the state of Voltage difference given in schematic form. The mirror images of the luminescent screen images 5 and 6 result from interchanging the unequal voltage applied to the electrodes 4, 3.

A special characteristic of the display is that which occurs when the voltage is equal, symmetrical arranged luminous lines surrounded by two shadow zones. This line If there is a voltage difference in two opposing movements, the fluorescent screen in general not completely coated single lines split up. The distance in that direction of the two moving lines is approximately the voltage difference that is applied to the electrodes Tensions proportional.

In Fig. 7, an embodiment is shown in which the sheet metal ring 5 is not approximately in the middle of the luminescent screen, but moved closer to the upper edge of the cap. the The resulting luminous patterns are shown in FIGS. 8, 9, 10. The length of the from the top of the screen The outgoing luminous line is somewhat shorter due to this special arrangement. By changing the voltage applied to the sheet metal ring 5, it is now possible to produce this luminous line according to FIG. 12 to extend completely or only partially over the screen zone or accordingly 11 and 13 almost or completely from the screen. The light pattern of the lower deflection system is also experienced generally such a shift. However, the sense of displacement is reversed. the The size of this shift in the luminous pattern corresponds to the greater distance between the lower one Luminous screen edge to the lower edge of the sheet metal ring 5 is reduced. This light pattern change can be completely or almost completely suppressed when the upper limit of light of the lower deflection system is placed deep in the upper edge of the screen. Instead of a stress shift in the sheet metal ring 5 the positive voltage of the top cap can also be changed. In this Case there is no or only an insignificant shift of the light pattern of the lower deflection system.

By a slot-like design of the upper part of the sheet metal ring 5 according to FIG. 14, 15, 16 can be those shown in FIGS. 5, 6, 9, 10, 11, 12 Switch off the overlapping of the luminous edge sectors that may be disruptive and shown. Figs. 17, 18, 19, 21 show the luminous pattern at a constant positive voltage applied to the ring 5 at different on the Electrodes 3, 4 applied equivalent voltages. 20 shows the luminous image in the event of a voltage difference the comparison voltage and an increase in the voltage applied to the ring 5 again. 22 shows the luminous image when it is lowered the voltage applied to the electrode 5.

In Fig. 23, an embodiment is shown in which a special display grid is applied will. This grid has in the vicinity of the intersection of the electrodes 3, 4 and the Cathode cover zone of the sheet metal ring 5 sealing turns or a smaller grid pitch. Even an uncovered zone on the cathode 1 at the level of the sheet metal piece 5 or at the level of the intersection point the comparison electrodes 3, 4 are expediently provided. It arises from it

the advantage of a smaller and more symmetrical bar current of the electrodes 3, 4, whereby the controllability of the individual systems and the tuning accuracy of the display tube is increased. In Fig. 24 an embodiment is given in which two separate sheet metal rings 5 α and 5 b are provided. This arrangement allows the extent of the individual light patterns on the screen to be influenced almost independently of one another. In Fig. 25 and 26 examples of luminous patterns are shown in which the voltage of the ring 5 b is kept constant and the voltage of the ring 5 α is changed. The luminous pattern in FIGS. 27 and 28 results when the voltage of the ring 5 α is kept constant and the voltage on the ring 5 b is changed. The luminous pattern of FIG. 29 corresponds to that of FIG. 28; the outer light sectors of the lower deflection system are switched off here in accordance with the exemplary embodiments in FIGS. 14, 15, 16 by fading out.

In FIGS. 30, 31, 32 examples are shown in which the holding supports 8 and 9 and the sheet metal piece 5 are replaced by a common sheet metal body. This results in a simplified system structure. The corresponding luminous patterns for the different deflection voltages correspond to FIGS. 17 to 22. In this case, in order to avoid unnecessary power consumption of the sheet metal body 5, the display grid 2 α can be in the part of the cathode circumference not used by the luminescent screen according to FIGS. 33, 34 , 35 are covered by a piece of sheet metal 2 b . The invention also provides for the display grating to be implemented in the various deflection systems with different winding spacings. This is indicated by an example in FIG. 36.

The luminance of the luminous images generated by the individual systems can thereby be influenced will. If this display grid is given a negative bias voltage with respect to the cathode, it can be thereby the luminous pattern caused by the upper deflection system either completely or only partially extinguish, while the luminance of the lower system is influenced only to a small extent will. In some cases, this effect occurs with the same lattice gradients and the same pretensioning in the individual systems in that the anode shape of the grid-anode distance of the individual systems are different from each other.

37, 38, 39 show a further embodiment of the invention. The luminescent screen 7 here represents a flat piece of sheet metal inclined with respect to the direction of observation. Of course, the cup-shaped screens listed in the previous exemplary embodiments can also be used in this case. The attachment of a transparent fluorescent screen, which is arranged perpendicular to the direction of observation and is excited to fluorescence by electron impact on the side rearward to the direction of observation, is also provided. In the embodiment shown in FIGS. 37, 38, 39, the cathode is preferably arranged in a plane which is perpendicular to the direction of observation. The cathode 1 is surrounded by a display grid 2, the sheet metal rings 5, 10, 11, the deflection struts 3α, 3b , 4c ·, 4b, to which the comparison voltages are applied. A voltage that is positive with respect to the cathode, preferably the luminescent screen voltage, is applied to the sheet metal rings 5, 10, 11. The mutual spacing of the individual luminous images on the luminous screen can be varied by the magnitude of the voltages applied to the rings. If the deflection electrodes 3 α and 3 b and the deflection electrodes 4 α and 4 b are connected to the voltages to be compared, a luminous pattern according to FIG Sheet metal piece .changed, the two luminous images generated by the systems are shifted against each other on the luminescent screen. For example, if there is a difference in voltage between the deflection electrodes 3, 4 in accordance with the luminous image in FIG. 41, when the voltage applied to the ring 5 is increased, a luminous pattern as shown in FIG. 43 results. By changing the voltage of the rings 10, 11, the expansion of the individual luminous images can be influenced separately or almost separately from one another. In FIG. 44, for example, the tension of the ring 11 was increased, in FIG. 45 the tension of the ring 11 was decreased. If the Eelektroden 3 α and 4 b joined together and attached to a constant voltage, the electrodes 3 b and applied to the comparison voltage 4a, this results in a light pattern in which not only the magnitude of the voltage difference of the individual light images, but also the height the voltage level of the reference voltage is represented by a change in position. 46 and 47 show the luminous pattern with the same voltage applied to electrodes 3 & 4a. However, this tension has a tension difference compared to the tension of the webs 2> a and 4b . 48 and 49 show roughly the same stress level of the webs 3b and 4a compared to the webs 30 and 4b as in FIGS. 46 and 47.

In this case, however, the webs 3 b and 4 a still have a small voltage difference between them. 50 shows the luminous image again with a voltage difference of the webs 3 & and 4a or 30- and δ with a changed voltage at the electrode 5. In the previous exemplary embodiments, the deflection electrodes were in the form of round struts which were parallel to each other and parallel to the cathode axis were arranged. 51 and 52 are an exemplary embodiment in which the control struts assume an inclined position below themselves and with respect to the cathode. The resulting luminous patterns are shown in FIG. 53 with the same voltage applied to the electrodes and in FIGS. 54 and 55 with different voltage applied to the electrodes

Stresses shown. There are light patterns with wedge-shaped luminous images that ensure high reading accuracy.

It goes without saying that the features of the individual exemplary embodiments can also be combined with one another. For example, the i in the Fig., 2, 3, 7, 14, 15, 16, 23, 24, 30, 31, 32, 33, 34, 35, 36 crossed struts due to split struts as shown in Fig. 37 , 38, 39, 51, 52, which can be connected crosswise or in the same direction inside or outside the system. The struts according to FIGS. 51, 52, which are not arranged parallel to one another and to the cathode, can also be implemented in the preceding examples either in the form shown in FIGS. 51 and 52 or also in a crossed form. The measurement voltages fed to the deflection electrodes can be amplified inside or outside the discharge vessel. Discharge arrangements can be used in which the voltage values of the deflection electrodes can be changed by a different control voltage. As a result, there is a shift in size of the luminous images generated by the deflection systems, in the special case of two adjacent deflection electrodes the change in luminous pattern already described by spreading the middle luminous line and enlarging the shadow zone. The charge arrangements suitable for this consist in a known manner of a system with several anodes arranged symmetrically around a cathode, the current of which can be influenced differently by several so-called asymmetrical control electrodes and influenced in the same way by a so-called symmetrically acting control electrode. These control anodes are connected to the display electrodes of the deflection system. In the operating state of the tube, the control anodes are connected to a positive voltage via external resistors, preferably via the same external resistors.

The display tube described can be especially used for the tuning of receivers for Use FM modulation or combined receivers for AM / FM modulation. In this In the case, lighting systems are preferred that have a voltage difference or voltage equality Show. If tubes without pre-amplification are used in this case, they will be used in this case electrodes of the lighting systems occurring in pairs, when using amplifiers the asymmetrical control electrodes, so connected to the switching points of the FM discriminator, that with precise adjustment to the center of the carrier, the voltage difference ο and when the Receiver, depending on the sense of the detuning, a negative or positive voltage difference occurs. A display of the carrier can take place in that the display grids of the deflection systems are connected to switching points that are negative or positive when a carrier arrives will. Form suitable switching points of this type

z. B. the negative or positive total voltage of the ratio rectifier, the grid of the limiter or interference suppressor, the anode or the screen grid of a regulated tube and the like possibly existing symmetrically acting control electrodes are used when using a Amplifier system with the control voltage of the FM part with combined FM / AM receivers the control voltage of the AM and FM part.

Claims (1)

PATENT CLAIMS: 1. Voltage comparison indicator tube with two electrodes connected to the voltages to be compared, in the case of the main patent 950 946 migrating in opposite directions into the symmetry position by crossing these electrodes Light pattern parts Equal voltage and light pattern parts migrating in opposite directions Voltage difference is displayed, characterized in that the separation points between the deflection electrodes (3, 4) of the individual display systems by a shielding electrode (5) are covered, so that the annoying overlaps of the luminous sector edges are avoided. 2. Voltage comparison indicator tube according to claim i, characterized in that for all Display systems use a common cathode. 3. Voltage comparison indicator tube according to claim 2, characterized in that the division the cathode is carried out for the purpose of arranging the various display systems in an axial or radial arrangement. 4. voltage comparison indicator tube according to claim i, characterized in that the Separating electrode is combined with the support brackets to form a common electrode. 5. voltage comparison indicator tube according to claim i, characterized in that the Separating electrode with the luminescent screen and the shielding cap to form an electro-optical system is united. 6. voltage comparison indicator tube according to claim 5, characterized in that the electron-optical System for changing the individual luminous images to one another is used. 7. voltage comparison indicator tube according to claim 5, characterized in that the electron-optical System used in addition to display purposes, for example to display the carrier in the case of frequency-modulated transmitters will. 8. voltage comparison indicator tube according to claim i, characterized in that each Display system comprises at least two relatively adjacent deflection electrodes. 9. voltage comparison indicator tube according to claim 8, characterized in that this Deflection electrodes are shown below and / or opposite the cathode. 909 665/26 ίο. Voltage comparison indicator tube according to Claim 8, characterized in that the voltages are the electrodes in the individual Deflection systems are fed alternately. 11. Voltage comparison indicator tube to Claim 8, characterized in that the electrodes of the individual display systems within or outside of the piston crosswise ίο or otherwise connected. 12. Voltage comparison indicator tube according to claim 8, characterized in that the The distance between the deflection struts in the individual systems is not the same. 13. Voltage comparison indicator tube according to claim 2, characterized in that the common cathode is surrounded by a common display grid. 14. Voltage comparison indicator tube according to claim 13, characterized in that the common display grids at the separation points of the individual deflection systems, sealing windings or has smaller lattice gradients. 15. Voltage comparison indicator tube according to claim 13, characterized in that the common display grids in the different display systems different grid pitches Has. 16. Voltage comparison indicator tube according to claim 3, characterized in that at radial arrangement of the display systems between the deflection electrodes of the individual systems one or two separating electrodes are arranged. 17. Voltage comparison indicator tube according to claim 16, characterized in that on the deflection electrodes the voltage to be measured and one to the separating electrode or electrodes constant positive voltage or voltage that changes during the measurement process is applied will. 18. Voltage comparison indicator tube to Claim 1, characterized in that each deflection system is provided with a display grille with the help of which the luminous images of the individual systems are extinguished or weakened will. 19. Voltage comparison indicator tube according to claim 1, characterized in that by Recesses in the shielding cap or a suitable one, possibly with the shielding cap connected electrode, position-invariable luminous images of individual systems are generated. 20. Voltage comparison indicator tube according to claim 1, characterized in that it for the combined display of FM and AM receivers or individually of FM or AM receivers is used. Considered publications: U.S. Patents Nos. 2394857, 2513908, 1630443, 2321855; French Patent No. 853 504; L. Ratheiser, "Rundfunkröhren", 1949, pp. 68 to 75; "Data and circuits of modern receivers and power amplifier tubes", 1940, N. V. Philips Gloeilampenfabrieken, Eindhoven, pp. 144 to 150; "Proceedings of the IRE", October 1947, p. 1158 until 1160. Legacy Patents Considered:
German Patent No. 950 946. For this purpose 2 sheets of drawings © 909 665/26 12.59